inVia Raman microscope used in breakthrough graphene research

Renishaw's inVia Raman microscope has been used in breakthrough graphene research

7th February 2013

A Renishaw inVia Raman microscope has been used in new research that addresses one of the major hindrances to the wider exploitation of graphene: the difficulty in growing large defect-free films.

An international team—led by Oxford University scientists Professor Nicole Grobert and Adrian Murdock— in collaboration with Renishaw plc and researchers from the Forschungszentrum Juelich (Germany) and University of Ioannina (Greece), used a Renishaw inVia Raman microscope to examine film thickness, strain and defects in graphene films.

Graphene is a single layer of carbon atoms and was the first two dimensional material to be discovered. It has very interesting electronic and mechanical properties; it is one of the most conductive materials known to science and has a breaking strength 100 times greater than steel.

Typically, when graphene is grown using chemical vapour deposition (CVD), the individual graphene flakes merge with a variety of different orientations, creating defects. In this work, titled ‘Controlling the Orientation, Edge Geometry and Thickness of Chemical Vapour Deposition Graphene', and published in the journal ACS Nano, it was found that the orientation of the underlying copper substrate could be used to guide the graphene flakes so they are aligned, and these defects are prevented.

Team member Dr Tim Batten, Raman applications specialist at Renishaw, said, “The inVia Raman spectrometer is a very powerful tool for investigating the properties of graphene. This work gives a much better understanding of CVD graphene growth, which will be important for manufacturing graphene on an industrial scale.”

In 2006 Professor Andrea Ferrari (University of Cambridge), used a Renishaw Raman spectrometer to conduct the first Raman characterisation of graphene. He used samples from its discoverers, Nobel Prize winners Professor Andre Geim and Professor Kostya Novoselov (University of Manchester). Since then, researchers worldwide have used data from Renishaw Raman systems in hundreds of scientific papers on graphene, greatly assisting in the understanding and development of this amazing material.

Image: Raman map of the 2D graphene band width for a CVD graphene sample. This image illustrates the variation in the number of graphene layers over the sample region, with bright red regions consisting of thicker material than darker red regions.

Raman map of the 2D graphene band width for a CVD graphene sample. This image illustrates the variation in the number of graphene layers over the sample region, with bright red regions consisting of thicker material than darker red regions.

This site uses cookies (including third party cookies). Some of these cookies are essential to make our site work properly and others are non-essential but help us to improve the site, including language and location settings and site analytics. You can read more about how we use cookies and how to configure or disable them on our site. By continuing to browse this site you agree to our use of cookies.